WO2006063928A1

WO2006063928A1 - Polyphase switching device comprising at least three similar interrupter units

Info

Publication number: WO2006063928A1
Application number: PCT/EP2005/056303
Authority: WO
Inventors: Bernd Bruchmann; Horst Waage
Original assignee: Siemens Aktiengesellschaft
Priority date: 2004-12-13
Filing date: 2005-11-29
Publication date: 2006-06-22
Also published as: DE502005005434D1; CA2590504A1; CN100594569C; DE102004061277A1; ES2312039T3; RU2389103C2; EP1825488B1; EP1825488A1; MX2007007089A; US20080105654A1; CN101073132A; RU2007126650A

Abstract

The invention relates to a polyphase switching device (1) comprising several interrupter units. Said interrupter units are equipped with a first and a second terminal. The terminals lie on a respective main axis (5) and the main axes of the individual interrupter units are aligned in parallel. All distances between the main axes (5) are different. The invention thus provides a multi-functional polyphase switching device (1).

Description

description

Multi-phase switching device with at least three similar Un ^¬ breaker units

The invention relates to a multi-phase switching device with at least three similar interrupter units, each having a first and a second connector, each lying on a major axis, the Hauptach- sen are aligned approximately parallel to each other.

Such a multi-phase switching device is known for example from the patent US 6,630,638 Bl. The local multiphase switching device has three interrupter units, which are each surrounded by a separate encapsulating. For connecting the breaker units to an electric power transmission network, outdoor bushings for introducing electrical conductors are respectively arranged on the encapsulating housings.

The encapsulating and thus also the inside ^{befindli ¬} Chen breaker ^{units of} the known multi-phase switching device are close together. In order to ensure a necessary spacing of air-insulated electrical conductors at the free ends of the outdoor bushings, they are each pulled apart like a fan. Due to the compact arrangement of the interrupter units to each other a small footprint for the electrical switching device is benö ^¬ taken. The retrofitting or expansion of the known poly-phase switching device with other modules, such as grounding switches or circuit breakers, however, is hardly possible due to the tight space. The invention has for its object to provide a multi-phase switching device, which is flexible and reserves sufficient reserves for the introduction of other modules.

The object is achieved ^{according to the} invention in a multiphase switching device of the type mentioned initially in that all distances of the main axes have different amounts from each other.

By choosing different amounts for the distances of the main axes of the interrupter units to each other a multi-phase switching device can be designed, which has a asymmetri ^¬ cal distribution of the interrupter units. The asymmetric distribution of different areas are provided to the switching device, the union for a nachträg ^¬ installation of additional modules, such as earthing switches, voltage or current transformers or the like are available. The different distances of the main axes to one another make it possible to provide areas of different sizes or volumes on the switching device in order to retrofit components of different sizes, such as switching devices, voltage transformers or other monitoring devices.

The interrupter units can for example be designed in such a way from ^¬ that two relatively movable con tact ^¬ pieces are arranged axially opposite each other and one or both contact pieces along the axis can be displaced. The terminals of the interrupter unit are in each case located at the ends remote from the switching point of the contact pieces. In such an embodiment, the main axis of the interrupter unit and the axis along which the Rela ^¬ tive movement of the contact pieces is approximately identical. The connecting pieces are then advantageously substantially ro ^¬ tationssymmetrisch configured and arranged coaxially to the axis at ^¬.

Advantageously, it can be provided that the main axes are arranged in a common plane.

With an arrangement of the main axes in a common plane, the switching device can be designed, for example, in a dead tank design. Due to the arrangements in a plane in connection with the choice of the distances of the main axes to each other are between the breaker units of the individual phases areas of different sizes for the installation of different sized elements available.

In this case, it can furthermore be advantageously provided that each of the interrupter units is surrounded by a separate encapsulating housing.

The sheathing of the interrupter units with separate Kapselungsgehäusen also allows the distances between the main axes ^¬ from each other depending on the site variable festzule ^¬ gene. Each of the encapsulating housing to the respective interrup ^¬ chereinheiten acts arc extinguishing respect, insulation strength, etc. independently of the other.

A further advantageous embodiment may provide that at least one outdoor bushing is arranged substantially radi- aler alignment with the main axis of the respective Kapselungsge ^¬ häuses for the electrical connection of the interrupter units, respectively. By means of outdoor bushings electrical lines can be safely inserted into the interior of the encapsulation ^¬ who. The radial alignment allows safe separation of live parts to the housing. For example, the encapsulating housing can consist of an electrically conductive material and can itself carry ground potential. This results in robust weather-resistant arrangements that can be used for example under difficult climatic conditions.

A further advantageous embodiment can provide that two outdoor bushings are each pivoted about the main axes with opposite sense of direction from a vertical and an outdoor bushing is arranged in the Senkrech- th.

Such a configuration may, for example, lead to Ausges ^¬ tion of fan-shaped each other arranged outdoor bushings of three phases of the switching device. As a result, a sufficient impact distance at the free ends of the outdoor bushings leading to different electrical potentials can be generated in a simple manner.

Furthermore, it can be advantageously provided that all free air ducts are pivoted about a maximum of 45 ° from a vertical respectively about the main axes, wherein an outdoor bushing is swung out with deviating from the other outdoor bushings direction sense.

In conjunction with the different distances of the main axes of the breaker units and a pivoting of all outdoor bushings, wherein one of the outdoor bushings with a different sense of direction ausge- is pivoted, the maintenance of sufficient strike widths between the outdoor bushings is guaranteed. In addition, with an arrangement of the interrupter units in a plane can be achieved that the height of the connection points at the free ends of the outdoor bushings is the same for all phases. This results in advantages in a cramped installation of the electrical switching device, for example, under a high voltage line. Compared with symmetrically fanned outdoor bushings in which the connection point of the centrally arranged passage is higher than the connection points of laterally pivoted outdoor bushings, a use of a switching device according to the invention is also possible on built-up areas of low height.

Furthermore, it can be advantageously provided that the switching device is a single-phase encapsulated switching device in dead-tank design and the switching device is a high-voltage circuit breaker.

Switchgear in dead-tank design are known for example from the prior art. A Ausges invention ^¬ taltung a high-voltage circuit breaker in Dead Tank construction is compatible with existing arrangements, that is, with a replacement of worn high-voltage circuit breakers can be as easily an inventive high-voltage circuit breakers are used.

It can be advantageously further provided that at least one outdoor bushing is flanged directly to a flange arranged on the encapsulating housing. By a direct flanging an outdoor bushing to the encapsulating a mechanically stabi ^¬ le unit arises. Vibrations of outdoor bushings due to switching operations or wind loads can be limited to a permissible level.

A further advantageous embodiment can provide that at least one outdoor bushing is flanged indirectly to an encapsulating housing with the interposition of a further housing assembly.

The intermediate construction of another housing assembly makes it possible to attach additional components in a compact form to the multiphase switching device. For this purpose, for example, the interior of the housing assembly can be used.

It can be advantageously provided that in the further housing assembly, a circuit breaker and / or a Erdungsschal ^¬ ter is arranged.

Due to the arrangement of disconnectors and earthing switches within a further housing assembly before this ßeren externa ^¬ environmental influences are protected. At the same time, the ^{environment is} protected against hazards which originate from the switching devices arranged in the interior of the housing group.

In addition, with the equipment of the multiphase switching device with a further housing assembly, the number of possible circuit variants is increased. This makes the multi-phase electrical switching device versatile. Thus, for example, be provided that freige ^¬ be switched on via the grounding switch and the disconnecting switch single transmission line sections, and these are then grounded. In the following, an embodiment of the invention is sche ^¬ matically shown in a drawing and described in more detail below. It shows the

Figure 1 is an end view of a multi-phase

Switchgear, the

Figure 2 is a side view of the Darge in Figure 1 ^¬ presented multi-phase switching device, Figure 3 is an end view of the BE from the figure 1 ^¬ known switching device with a switch as well as the Freilufterdungs-

Figure 4 is a side view of an electrical switching ^¬ device with outdoor bushings and interposed built other housing assemblies.

1 shows a multi-phase switching device 1. The multi-phase switching device has three phases A, B, C. Each of the three phases A, B, C is associated with a separate encapsulating housing 2, 3, 4. The enclosure housing 2, 3, 4 are each ^¬ weils made of an electrically conductive material and surrounding an interrupter unit of a high voltage circuit breaker. The encapsulating housings 2, 3, 4 have a substantially tubular structure. Along the pipe axes of the enclosure housing 2, 3, 4 are in the interior of Cape ^¬ selungsgehäuse 2, 3, 4, the respective interrupter units of the phases A, B, C arranged. In FIG. 1, the main axes project vertically out of the plane of the drawing. A main axis 5 of the phase C can be seen in a side view in FIG. The viewing direction of the representation of FIG. 2 is identified by an arrow 6 in FIG. By way of example, an interrupter unit 11 is shown in FIG. The interrupter unit 11 has a first contact piece 12 and a second contact piece 13. The contact pieces 12, 13 are coaxial with the main axis 5. The first contact piece 12 is tulip-shaped, the second contact piece 13 is designed bolt-shaped. The second contact piece 13 is displaceable via a drive device 14 along the main axis 5. The connecting pieces are in ^¬ We sentlichen rotationally symmetrical and the contact pieces 12, 13 are arranged on the side remote from the switching member.

For supplying the electrical lines to the interrupter units located in the interior of the encapsulating housings 2, 3, 4, a first and a second outdoor bushing 7a, b, c, d are respectively arranged on the encapsulation housings 2, 3, 4 on the jacket side. The main axes of the phases A, B, C are each arranged in a common plane and aligned parallel to each other. All distances of the major axes of the phases A, B, C are different from each other. Thus, the distance between the major axes of the phases A and C is greater than the distance between the major axes of the phases A and B and greater than the distance between the major axes of the phases B and C. Whereby the distance between the major axes of the phases A and B is greater than the distance between the major axes of phases B and C.

In addition to the arrangement shown in Figure 1, however, can also be provided that the main axes are indeed arranged parallel to each other, but are in different levels, so that a so-called triangle arrangement arises. Also in this case, the distance of all major axes is different from each other. Furthermore, it can also be provided that one or more of the outdoor bushings of the phases A, B, C are in a vertical. In order to ensure a sufficient impact distance S at the free ends of the outdoor bushings, the axes of the outdoor bushings are pivoted out of a vertical. The axes are all steered by the same amount from ^¬ . The outdoor bushings of phases A and B are each deflected with the same sense of direction. The outdoor ^{bushings of} the phase C are indeed deflected by the same amount but with different sense of direction. This results in an arrangement in which the connection points of the outdoor bushings are at the same height, with approximately equal distances S between the connection points of the outer outdoor bushings and the middle outdoor bushing present.

In the asymmetrical distribution of the main axes shown in Figure 1 arises between the phases A and B, a receiving space for the arrangement of other modules such as earthing switches or the like. Between phase B and C, such a space is not provided. Due to the asymmetrical arrangement, the entire multi-phase switching ^{¬ device is} rotatable about a vertical axis, so that the space provided for retrofitting further modules space in the desired La ^¬ ge is rotatable.

FIG. 3 shows by way of example the equipment of the multiphase switching device shown in FIG. 1 with an outdoor earthing switch 8. The Freilufterdungs- switch 8 has at each stage a pivotable rod which are rotatably mounted near the base of the outdoor bushings 7a, 7b, 7c. There they are also connected to the earth ^¬ potential. For grounding, the earthing rods can be pivoted upwards into the position shown in FIG be and there in a mating contact at the free end of the respective outdoor bushings 7 a, 7 b, 7 c retract. At the two outer phases A, C, the earthing rods are arranged on the outside. At the middle phase B, the earthing bar is arranged in the space obtained by the asymmetrical distribution of the breaker unit. Due to the similar but made with different sense direction swiveling and thus achieved the same height of the connection points of the outdoor bushings similar grounding rods on the free air earthing switch 8 can be used for all three phases.

4 shows a further embodiment of a phase ei ^¬ nes multi-phase switching device, wherein the Freiluftdurchfüh- ments Ie, 7f are flanged with the interposition of a respective further housing assembly 9a, 9b to the encapsulating housing 10 ^¬ . In the interior of the other housing assemblies 9a, 9b, for example, disconnectors or earthing switches can be arranged. By means of the circuit breaker, for example, over the outdoor bushings Ie, 7f introduced into the interior of the encapsulating housing 10 Leiterzug can be separated. By means of the earthing switch, the corresponding conductor can be acted upon with ground potential. Inside the Kapselungsge ^¬ housing the circuit breaker or earthing switch are protected against external environmental influences. Furthermore, the under

High voltage potential standing outdoor bushings further away from the encapsulating housing 10 flanged to this medium ^¬ bar. As a result, a threat to operating personnel is avoided because high-voltage parts are further spaced from this.

Claims

claims

1. polyphase switching device (1) having at least three gleichar ^¬ term breaker units (11), each having a first and a second connector, each lying on a main axis, wherein the major axes are aligned approximately parallel to each other, characterized in that all distances of the Main axes have mutually different amounts.

2. Multi-phase switching device (1) according to claim 1, characterized in that the main axes are arranged in a common plane.

3. Multiphase switching device (1) according to any one of claims 1 or 2, d a d u r c h e k e n e c e in that each of the interrupter units (11) by a separate capsule housing (2, 3, 4) is surrounded.

4. Multiphase switching device (1) according to claim 3, characterized in that for the electrical connection of the interrupter units (11) each at least one outdoor bushing (7a, b, c, d) with a substantially radial orientation to the main axis of the respective encapsulation housing (2, 3, 4) is arranged.

5. Multiphase switching device (1) according to claim 4, characterized in that two outdoor bushings (7 a, b, c, d) in each case about the main axes with opposite sense of direction from a Vertically pivoted and an outdoor bushing is arranged in the vertical.

6. Multiphase switching device (1) according to claim 5, characterized in that all outdoor bushings (7 a, b, c, d) are pivoted by a maximum of 45 ° from a vertical respectively about the major axes, wherein an outdoor bushing with the other outdoor bushings ( 7a, b, c, d) is deviated deviating sense of direction.

7. Multiphase switching device (1) according to one of claims 1 to 6, d a d e r c h e c e n e c e s in that the switching device is a single-phase encapsulated switching device in

Dead tank design is and the switching device is a high voltage circuit breaker.

8. Multiphase switching device (1) according to one of claims 4 to 7, in that a at least one outdoor bushing (7a, b, c, d) is flanged directly to a flange arranged on the encapsulating housing (2, 3, 4).

9. Multiphase switching device (1) according to one of claims 4 to 7, d a d e r c h e c e n e c e in that at least one outdoor bushing (7 a, b, c, d) is indirectly flanged to an encapsulating housing (10) with the interposition of a further housing assembly (9a, 9b).

10. Multiphase switching device (1) according to claim 9, characterized in that in the further housing assembly (9a, 9b), a circuit breaker is arranged.

11. Multiphase switching device (1) according to claim 9 or 10, in that a grounding switch is arranged in the further housing assembly (9a, 9b).